Preparation of organosilicon halides



' Patented' Aug. 7,

" production at Rochow, Serial No.. 412,459, filed. concurrently- 2,380,996 FICE h s 23mm x rnsrm'rros or oaosnosmoou mamas smile" a. llochow and wnmn Ll'atnode, some ,nechdy. N. Y.,' signers-to General Electric Company, corporation or New York I No ; This invention relates to the preparation of organosilicon halides and more particularly to the halides.

In the copending application of Eugene ,G.

hydrocarbon-substitu ed silicon herewith and assigned to the same assignee as the present invention; is disclosed and broadlyclaimed the method oi' preparing orsanosilicon halides, more particularly hydrocarbon-substiide.

tuted silicon halides, which comprises efl'ecting reaction between silicon and a hydrocarbon hal- The present invention diil'ers from the inventlon claimed in the above-identified Rochow application in that it is directed specifically toa method oi preparing hydrocarbomsubstituted silicon halides; e. g., methyl silicon chlorides,

-wherein is .utilized a solid, porous contact m'ass of the kind disclosed and claimed in thecopending application of'Winton I. Patnode, Serial No.

412,481, also filed concurrently herewith and assigned to the same asslgnee as the present invention. i

It was known priorto our invention that hydrocarbonhalides could'be caused to react with elements other than silicon. For example, the reaction of hydrocarbon halides with magnesium in certain solvents to yield the so-called "Grisnard reagen is well known. Another exampl is the reaction of zinc or the zinc-copper couple with ,alk'yl halides to give alkyl zinc halides similar in with methyl bromide or iodide in liquid state in chemical behavior to the Grignard reagent. Zinc dimethyl also has been prepared by heating zinc a sealed tube. All such reactions, are liquid 'phase reactions.

The reaction of hydrogen chloride with silicon also was known. Thus,'Combes icompt. rend., 122,531 (1896)] obtained a mixture of approximately 80% trichlorosilane (silicochloroform) and 20% silicon tetrachloride by passing hydrogen chloride through an iron tube filled with silicon heated to 300 to 440 C. i

. It also'was known prior to ourinvention'that various hydrocarbon-substituted silicon halides .could be produced. The known methods of preparing such substituted silicon halides generally have involved the use of the well-known Grignard reagent. Such-a inethod of preparing methyl silicon chlorides is described, for example, in Rochow copending application Serial No. 287,787,

filed August 1, 1939. The present invention provides an improved process for producing hydrocarbon-substituted silicon halides at lower cost than is possibleiby' the use oi the 'Grignard reagent. 1

Brieily described, our invention residesin the.

, improved method 01- preparing organosiliconhalides, more particularly hydrocarbon-substituted Applfcatlpn September 26, 1041', s" SerialNoJlZAflO I 1: Claims. (Chem-s01) I silicon halides, e. g., alkyl silic'onchlorides; bromldes, etc., aryl silicon chlorides, bromides, etc., which comprises efl'ecting reaction between a hydrocarbon halide, e. g., an alkyl chloride; bromide, etc., an and chloride, bromide, etc.. and the silicon component or a solid, porous-contact mass comprising essentiallysilicon and a, metallic catalyst (e.' g., copper) tor the reaction. Advantageously we use a mass ofisolid, porous contact bodies obtained by firing under reducing condi- .tions a molded mixture of powdered silicon and a powdered metallic catalyst for the reaction has tween silicon and a hydrocarbon halide.

One specific method feature 01' our invention is the new and lmprovedmethod of preparing, for

example, methyl silicon chlorides which comhydrocarbon halide; heating the said 5 methyl tion is'the method which comprises causing gaseous*metlwlchloride or other hydrocarbon halide in gaseous or vapor state to react with the silicon 1 component of a solid, porous contact mass obprises bringing methyl chloride, more particular- 13? gaseous methyl chloride, into contact with a mass ot,solid,'porous, molded bodies comprising essentially silicon, and copper or other metallic catalyst for the reaction between silicon and a chloride and silicon-containing mass at a temperature sumciently high to eilect reaction 'between the said-methyl chloride and the silicon oi the said mass, and recovering the methyl silicon chlorides.

' Another specific method feature of this inventained by ilring under reducing conditions porous bodies formed, as by molding, from a mixture of powdered silicon .and powdered copper or other metallic catalyst for the reaction, said reaction being carried out within the temperature range of 200 .to 500 O. or more, and recovering the hydrocarbon-substituted silicon halides. For example, the eiiiuent gaseous reaction products may be cooled by suitable means to obtain a condensate comprising hydrocarbon-substituted silicon halides. specifically methyl silicon chlorides.

It was quite surprising and unexpected to find that a hydrocarbon-substituted silicon halide could be produced by reaction between a hydrocarbon halide and the silicon component of a solid, porous contact mass consisting substantial ly of silicon and a metallic catalyst forthe reaction, especially in 'view of the fact that silicon is commonly considered tozbe a metalloid ,and

. shows little or no resemblance to zinc, sodium, magnesium and the other highly electropositive metals heretofore known to react with hydrocarb n halides.

In order that those skilled in the art better may understand how the present invention may be carried into effect, the following illustrative examples thereof are given, all percentages are byweight.

" A strea'moi .passing from the exit end oi the reaction tube. at a temperature or the order-oi u t'l gaseous.methylchloridewas Silicon crushed to pass a Bil-mesh standard screen -35o 'c'. was maintained Within .into 'a heated tube where it contacted a solid, porous, molded contact mass prepared as lollows':

was mixed with fine copper powder-I in the/ratio or, by'weight, 80 pa'rts'ot the former-to of the latters 'lhe resulting unii'orm mixture-was into cylindrical pills or pellets 95-inch in diameter by .%-inch in height. The pellets were? [fired in hydrogen for 2' hour-sat 1050'" c. I

was maintained within tube." The Products were condensed minus 12' C.'

j The following data were obtained during the ,j the emcient operation at the beginning or therun, as well as the inemcient operation at the end when the silicon in the contact mass is nearly depleted. Maximum yield oi'the product, which comprises .a mixture oi methyl chlorosilanes (methyl silicon chlorides), during the most emproximately the stated percentages;

.4 reaction tempciatureoi the cram-gonzo c: 1 m

e tube. The productspassingfromthe exit 'end of the reaction tube were condensed.- A typical'condensate contains the following compoundsin ap I P r e t Methyl silicon trichloride 42 :Dimethyl silicon dichloride 88 Trimethy'lIsilico'n chloride 71:0 Silicochloroi'orm l. 2 to 4 Silicon 'tctramethyl 1 to 2 solid, molded, reduced contact mass prepared.

\ from a mixture of, by weight,'80} parts powdered .168 Pounds 01' product per hour 038i Pounds 01' product per) pound-0t. methyl chloride i 0.518; Pounds of product'per' pound oI-contact v 1 "Q 3.12 Pounds of product. per-pound of silicon 4.93 Per centsilicon'used 79.3

silicon and 20 parts powdered copper as described a under Example 1. A reaction temperature of approximately 350 c. wa's maintained within' the tube."- The productspassing-i'rom the exitend of the'r eaction tube were condensed Atypical con-- 'ldensate contains the'following compounds in approximatelythe stated percentages: Q Percent, Dimethyl silicon dichloride s l8 Mthyl silicon trichloride 6t0 12 U Astream oi gaseous methylchloride waspassd clent stages of the operation are approximately 50 per cent greater then shown above for thepounds of product obtained .per pound of methylchloride.,- Fractionation or the condensate showed.

that it consisted .mainiy oi dimethyl dichloro-" silane (dimethyl silicon dichloride) and'methyl trichlorosilane (methyl silicon Itrichloride) i y Example 2 Same as Example I with the exception that a reaction temperature or the order of 300 C. was maintained in the tube. Thetollowing data were Erdmpie S into a heated tube where it contacted porous pellets produced by molding a mixture of 98 per cent;

powdered silicon and 2 percent powdered copper. The molded pellets were d ed in hydrogen to! 20 minutes at 1030" to .1080" 1:. prior to use. A re action temperature 01' approximately 350 ,'C.'was maintained within the reaction tube. The prod-. uctspassing from the exit end'oi" thereaction tube were condensed.- A typical condensatecontains the following compounds inapproximht'ely the stated percentages:

. Per cent Dimethyl silicon dichloride .795

Methyl silicon trichloride -5 to 7 Example 6 -Methyl chloride in'gaseous' state was passed into' a tube charged with porous pellets produced by molding a mixture 01. 90 percent powdered sillcon'and 10 per cent powdered nickel. The molded pellets were fired in hydrogen for 15 minutes at obtained during the test: 7

Total reactiontime, hours f 140 Pounds of product per hour 0.401 Pounds of product per-pound of methyl chloride I 0.626 Pounds of productper pound oi contact 7 888 2.65

Pounds of product per pound or silicon .uiled V 5.05 Per, cent silicon'used .644 As in Example 1, the aboye figures are basedon the total reaction period.

' Ezamplel A stream of gaseous m'ethyl chloride waspassed -i'nto-a heated tube where it contacted a porous,

solid contact mass produced by molding a mix- .ture of 90 per cent powdered silicon and 10 per cent powdered copper into the form or pellets. (The comminuted silicon was oi such fineness that approximately 80 per cent passed througha 325-rnesh standard screenwhile approximately 20 per cent was retained on the screen. The comminuted copper was or approximately 400- mesh particle A-reaction temperature of 935 to 955" C. 'prior to use.' A reaction temper,

ature of approximately 350" C; was maintained within-the tube. The products passing from the exit end of the reactiontube were condensed. A

typical condensate contains the following com pounds in approximatelythe stated percentages:

- Per cent Methyl silicon trichloride 48 Dimethyl silicon dichloride 13.5

- Silicon -tetrach10ride 1 0 to 20 Silicochloroform 5to10 Emm pzer; Methyl chloridein gaseous state was passed into. a tube charged with porous pellets produced by molding a mixture of 90. per cent powdered silicon and 10 per cent powdered antimony. The molded pellets were tired in hydrogen for 15 minutes at 620 C. A reaction temperature of the order 01350" C. was maintained within the reacjtion tube. A typical condensate contains the-lol- Silicon tetrachloride to'20 Example 8 Ethyl chloride was allowed to evaporate into a" tube filled with a solid, porous, molded, contact teredin. a hydrogen atmosphere at'a temperature of about 1050 C. The sintered bars'were broken 'up into lumps approximately %-inch in size. A vertical reaction tube was charged with ,these lumps. Bromchenzene was allowed to drip into "the .reaction tube,. which was maintained mass produced by .molding a mixture of 90 per cent powdered silicon audio per cent powdered l 1 copper in the Iorm of pellets. 'I'l'ie'mo'ldmellets were fired in hydrogen at -l050 C. for2 hours. The reaction temperature was maintained at 300 to 325 C. The reaction products condensed in the form of a yellow, fuming liquid which, upon iractional distillation, was found to contain approximately 2'7 per centethyl silicon 'trichloride.

v26 per cent diethyl silicon dichloride and .37 per cent silicon tetrachloride.

' Ezc1riple 9 A glass tube was packed with porous coppersilicon pellets prepared as described "under Example 1: The tube was heated in a, combustion furnace while a slow stream'of'methyl bromide ring phenyl silicon bromides,

withi'n'the temperature range oi 380 to 475 C. v.

The bromobenzene,-therefore, was in the vapor phase during the reaction period. The products passing i'rom the exit end 01' the reaction tube were condensed, yielding a condensate compris- It will be understood, 01' course, by those skilled inthe art that our invention is not limited to the specific, hydrocarbon halidesnamed in the above illustrative examples and that any other hydro- -carbonhalide may be employed as a reactant not limited thereto, the vapor'phase reactions are may be directed to the production of the desired was passed through it. At approximately 2.75 C.

reaction occurred between the methyl bromide and the silicon. A yellow liquid was readily condensed from the unreacted methyl bromide. From this liquid, methyl tribromosilane lboil'ing point 133.5 0.), and dimethyl dibromosilanej (boiling point 112.3" .C.) wer tional distillation.

Example 10 the tube were condensed, yielding a yellow liquid comprising, ethyl silicon bromides.

. Example '11 Methyl iodide was allowed to drip into a sloping reaction tube charged with porous pellets formed from a.mixture of 90 percent silicon and 10 per cent copper and fired in hydrogen as described under Example 1. The tube was heated within isolated by frac organo-silicon halides ,with a minimum a: by-

products.

Likewise the invention is not limited to the specific temperatures or. temperat e ranges mentioned in'the examples. Howe er, the reaction temperature should not be so high asto cause an excessive deposition of carbon upon the unreacted silicon during thereaction. In general,. the reaction temperature to be used will vary with, for example, the particular hydrocarbon halide employed, the particular catalyst used arid the yields of the specific reaction prod,- ucts desired to beobta'ined from a particular starting hydrocarbon halide. Forexample, by varying the temperature of reaction within the temperature range of, say, .200 to '5 00 0;, the proportions oi the individual products obtained when methyl chloride; is brought into-contact with silicon can be varied and,-also, the overall rate oireaction. At temperatures oi the order of 200 C. the reaction proceeds much more slowly than at reaction temperatures around 250 to 400 C. At temperatures much above 400 C., in the case of methyl chloride for example, there is a vigorous exothermic reaction which generthe temperature range of 300 to 310 C. Fifty-- seven (57.) grams of methyl iodide were passed into the heated tube over a period of-2 hours. A

dark red liquid issued fromthe condenser affixed to the reaction tube. This liquid was distilled at atmospheric pressure. Besides 'unreactecl methyl iodide, there was obtained a. high-boiling liquid comprising methyl silicon iodides.

Example 12 Gaseous methyl fluoride was passed into a tube filled with porous pellets. formed of 90 per cent silicon and 10 percent copper and fired in hydrogen as described under Example 1. The reaction tube was heated at a temperature of the order oi 370 C. The products passing from the exit end of the tube were condensed. The condensate,

ally results in an undesirable deposition oi car bon on the contact mass, thereby lessening its efilciency. Although methyl silicon chlorides in varying yields can be produced by eii'ecting reaction betweenmethyl chloride and the silicon component of the solid, .porous contact mass at various temperatures within the temperature range of 200 to 500, optimum results usually are obtained within the more limited range of 250 to 400 C.

The solid, porous contact masses used in carrying our invention into efiect may be produced, for example, by molding a mixture comprising essentially silicon and a metallic catalyst for the reaction between silicon and a hydrocarbonhalide. Examples of such catalysts are copper, nickel, tin, antimony, manganese, silver and titanium. We advantageously may use solid, po-

rous contact bodies obtained by firing under reducing conditions a molded mixture of powdered silicon and a powdered metallic catalyst for the reaction, specifically copper. The molded mass is fired in a reducing atmosphere at a temperature suificiently high and for a period sufllcientinto the form 01' bars, which thereafter were sin- A -4-" ly long to activate the potentiallyyactivecatalyst. A i initially it is catalytically inactive, orto' in 'crease its-activity, it initially it is notso catanormal temperatures.

7 fasoopoe lytically active as may be desired. heat treatment increases the hardness and mechanical strength the contact mass, but isnot so 'drastic as to cause theporous mass'to be cmverted into "a nous-Porous body; During thisiirmetallic oxides, the contact mass are reduced.

' The flred mass. s cooled in a'-1non-oxidizing 'atmospher'e to a temperature at or approaching,

Another method oi producing porous, solid contact masses used, in carrying the present in- '=ing treatment, any reducible componentae. g.,

vention into effect is to. form a Mom mixture oi powdered silicon and powdered metallic catajlyst, and fire this mixture in a reducing atmosphere at a temperature sumcientlylhigh to efi'ect sintering thereof and to impart rigidity thereto. The fired mass then is broken up to p obtain porous lumps of a desired size.- a

As pointed out inPatnOde application serial No, 412,461; wherein the contact masses employed in practicing the present inventionare more fully described and specifically v claimed, the proportions of components constituting these 'contact masses may be varied considerably.

Preferably, "however, the solid, porous contact masses consist'substahtially of a preponderant containing the products ofreaction-will'benoted by comparing the yields of individual compounds present in the condensates ob Examples} to '1.

inclusive! s enact of variations in the compositions ot the contact masses used in practicing the Present invention upon the composition 01' the condensate By eflecting-reaction between a. hydrocarbonhalide and silicon when the 'lattergis in the lorm' oi .a solid, porous contact mass (preferably a solid, porous, molded reduced contact massL. I

consisting essentially opsilicon' and a metallic catalyst for the reaction, e. g., copper, the reaction proceeds more satisfactorily and with betcontrol or the process .and of. the'products or reaction than when the silicon and ;catalyst a are associated together in other form.

Y The present invention provides a new and imit proved method for the productionoiaikyl silicon proportion'oi' silicon and a minor proportion 01 copper or other metallic catalyst for the reaction between silicon and a hydrocarbon halide. A more specificexample or such a; con

,ta'ct mass is'the product of firing under'reduc- -ing vconditions a moldedmixture of; bi! weight, from2 to per cent powdered metallic catalyst, specifically copper, and from 98 .to 45 per cent powdered silicon. Particularly good results from I a practical standpoint are obtained with solid, porous contact bodies produced by firing under reducing conditions a molded mixture of, by

weight, from .5 to 25 per cent powdered copper point of maximum yield of reaction products per pound oi methyl chloride ordinarily accrues from using solid, porous contact masses containing much over 20 or 25per cent copper. The rate of conversion of the methyl chloride to methyl. silicon chlorides falls oil as the silicon is used up,

.but it falls of! much more rapidly when con tact masses oi low copper content (e. g.,,from 1 to 5 per cent) are used. These facts are'substantiatedby the data shown below:

ing glass halides (e..g., methyl, ethyl, propyl, hutyhamyl,

isoamyl, hexyl, etc; silicon halides), the aryl sill. 1 con halides (e. g.. phenyl silicon halides, etc.) the aryl-substituted aliphatic silicon. halides (e. g.,

phenvlethyl silicon-halides, etc) and the ML phatic-substituted aryl silicon halides ,(e. g., toiyl silicon halides, etc.)

.- The products of this invention have utility as intermediates in the preparation or other products. For instance, they may be employed as starting materials for the manufacture ofsilicoh resins. They also may be used as agents for treating .waternon-repellent bodies to make them water-repellent-as disclosed andclaimed in the copending applicationpof Winton 1. Pat-' node, Serial No. 365,983, filed November 16, 1940,,

and assigned to the same assignee as the present invention. They also maybe employed for treat"- fibers in continuous ,fllament or' other form.

What we claimas new and desire to secure by Letters Patent 01' the United States is:

1. The method of preparing organosilicon halides which comprises'eil'ecting reaction between 1 a hydrocarbon halide and the silicon componentpi a solid,.porouscontact mass obtained by firing under reducing conditions a mixture of powdered silicon and apowdered metallic,cata- V lyst for the said reaction.

,2. The method of preparing organosilicon halides which comprises eii'ecting reaction between rides which comprises effecting reaction between lyst for the said reaction. 4. The method of preparing and silicon hal-, ides which comprises efl'ecting reaction between Per cent copper in solid, porous contact mass 2. s .5' 10' so Pounds product per pound 011,01 at P d 113d Ytllli ndfifflni 0.63 .0. 71 0.77 0.73,

ouns no perpoun a middlgoi i'ufi 0. 29 0. 43 0. 59 0. 63 Pounds product peigdpound CH Cli 4 when reaction peri is Super cent com leted 0.23 0.36 0.43 0.45 Poun s product per pounds I math 1 chloride charged to reaction tube uring total reaction period. n- 43.0 55. 0 64. 5 d3. 5

an alkyl chloride, and the silicon component oi solid, porous contact bodies obtained by firing under reducing conditions a moldedmixture oi powdered silicon and a powdered metallic cataan aryl halide and the silicon component oi solid,

porous contact bodies obtained by firing under reducing conditions a molded mixture of powdered silicon and a'powdered metallic catalyst- 'for the said reaction.

-5. The method of preparing phenyl silicon hal I I of solid,.porous contact bodies obtained by firing pnderreducing conditionsa molded mixture of powdered 'siliconand copper.

2,880,996 6. The method of preparing hydrocarbon-substituted silicon "halides which comprises efiecting reaction between a hydrocarbon halide in a vapor state and the silicon component of a solid,

porous contact mass obtained by firing under reducing conditions a molded mixture of silicon and'copper.

7. The method of preparing eikyi silicon chlorides which comprises eflecting reaction between powdered an alkyl chloride in a vapor state and the silicon component of a solid, porous contact mass ob-L tained by firing a molded mixture of powdered silicon and copperunder reducing conditions.

8. The method of preparing methyl silicon chlorides which comprises efi'ecting reaction be tween methyl chloride and the silicon component of a solid. porous mass obtained by firing under per, the silicon constituting a preponderant proportion of the said mass.

11. The method of preparing methyl silicon chlorides which comprises'eflecting reaction between gaseous methyl chloride and the silicon component of a solid, porous contact mass obtained by firing under reducing conditions molded bodies formed from a mixture of by weight, from 2 to 45 per cent powdered copper .and from 98 to 55 per cent powdered silicon.

12. The method of preparing methyl silicon chlorides which comprises bringing gaseous methyl chloride into contact with a mass of solid,

porous bodies obtained by firing at sintering temperatures and in a reducing atmosphere apowdered mixture of silicon and copper, heating the said methyl chloride and mass of bodies at a temperature sufliciently high to effect reaction between the methyl chloride and the silicon component of'the said-mass, and recovering the methyl silicon chlorides. 13. vThe method which comprises causing gaseous methyl chloride to react with the silicon component of a solid, porouscontact mass ob- 10. The method of" preparing methyl silicon chlorides which comprises eflecting 'reactionbetween gaseous methyl chloride and the silicon component oi solid, porous contact bodies obtained by firing under reducing conditions a mixture of powdered silicon and powdered cop- Patent No. 2,580,996.

CERTIFIGA'I'E or coaREcrIoN EUGENE c. ROCHCW; ET AL.

tained by firing under reducing conditions bodies formed from a mixture of powdered silicon and powdered copper, said reaction being carried out within the temperature range of-200" to 500 C., and cooling the eflluent gases to obtain a condensate comprising methyl silicon chlorides.

. EUGENE c. Rocrrow. .WINTON 1. PATNODE.

: August 7, 19145.

It is hereby certified that error appears in the printed specification oithe above numbered patent requiring correction "as follows: Page 2, first column, line 10', Example 1., for -"5/5-inch" read --5/Binch--;-and that the said Letters Patent should be read with this correction therein that the same may conform to the record of the case in'the Patent Office.

Signed and-sealed this. 27th day of 'Noyember, i l. D 1914.5.

(,Seal) Leslie Frazer" First Assistant Commissioner of Patents.

2,880,996 6. The method of preparing hydrocarbon-substituted silicon "halides which comprises efiecting reaction between a hydrocarbon halide in a vapor state and the silicon component of a solid,

porous contact mass obtained by firing under reducing conditions a molded mixture of silicon and'copper.

7. The method of preparing eikyi silicon chlorides which comprises eflecting reaction between powdered an alkyl chloride in a vapor state and the silicon component of a solid, porous contact mass ob-L tained by firing a molded mixture of powdered silicon and copperunder reducing conditions.

8. The method of preparing methyl silicon chlorides which comprises efi'ecting reaction be tween methyl chloride and the silicon component of a solid. porous mass obtained by firing under per, the silicon constituting a preponderant proportion of the said mass.

11. The method of preparing methyl silicon chlorides which comprises'eflecting reaction between gaseous methyl chloride and the silicon component of a solid, porous contact mass obtained by firing under reducing conditions molded bodies formed from a mixture of by weight, from 2 to 45 per cent powdered copper .and from 98 to 55 per cent powdered silicon.

12. The method of preparing methyl silicon chlorides which comprises bringing gaseous methyl chloride into contact with a mass of solid,

porous bodies obtained by firing at sintering temperatures and in a reducing atmosphere apowdered mixture of silicon and copper, heating the said methyl chloride and mass of bodies at a temperature sufliciently high to effect reaction between the methyl chloride and the silicon component of'the said-mass, and recovering the methyl silicon chlorides. 13. vThe method which comprises causing gaseous methyl chloride to react with the silicon component of a solid, porouscontact mass ob- 10. The method of" preparing methyl silicon chlorides which comprises eflecting 'reactionbetween gaseous methyl chloride and the silicon component oi solid, porous contact bodies obtained by firing under reducing conditions a mixture of powdered silicon and powdered cop- Patent No. 2,580,996.

CERTIFIGA'I'E or coaREcrIoN EUGENE c. ROCHCW; ET AL.

tained by firing under reducing conditions bodies formed from a mixture of powdered silicon and powdered copper, said reaction being carried out within the temperature range of-200" to 500 C., and cooling the eflluent gases to obtain a condensate comprising methyl silicon chlorides.

. EUGENE c. Rocrrow. .WINTON 1. PATNODE.

: August 7, 19145.

It is hereby certified that error appears in the printed specification oithe above numbered patent requiring correction "as follows: Page 2, first column, line 10', Example 1., for -"5/5-inch" read --5/Binch--;-and that the said Letters Patent should be read with this correction therein that the same may conform to the record of the case in'the Patent Office.

Signed and-sealed this. 27th day of 'Noyember, i l. D 1914.5.

(,Seal) Leslie Frazer" First Assistant Commissioner of Patents. 

